Dissecting the Functional Consequences of De Novo DNA Methylation Dynamics in 
Human Motor Neuron Differentiation and Physiology

Ziller, Michael J.; Ortega, Juan A.; Quinlan, Katharina A.; Santos, David P.; Gu, Hongcang; Martin , Eric J.; Galonska, Christina; Pop, Ramona; Maidl, Susanne; Pardo, Alba Di; Huang , Mei; Meltzer, Herbert Y.; Gnirke , Andreas; Heckman, C. J.; Meissner, Alexander; Kiskinis, Evangelos

doi:10.1016/j.stem.2018.02.012

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Dissecting the Functional Consequences of De Novo DNA Methylation Dynamics in Human Motor Neuron Differentiation and Physiology

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Galonska, Christina
Dept. of Genome Regulation (Head: Alexander Meissner), Max Planck Institute for Molecular Genetics, Max Planck Society;

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Meissner, Alexander
Dept. of Genome Regulation (Head: Alexander Meissner), Max Planck Institute for Molecular Genetics, Max Planck Society;

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Zitation

Ziller, M. J., Ortega, J. A., Quinlan, K. A., Santos, D. P., Gu, H., Martin, E. J., et al. (2018). Dissecting the Functional Consequences of De Novo DNA Methylation Dynamics in Human Motor Neuron Differentiation and Physiology. Cell Stem Cell, 22, 1-16. doi:10.1016/j.stem.2018.02.012.

Zitierlink: https://hdl.handle.net/21.11116/0000-0000-DFEB-D

Zusammenfassung

The somatic DNA methylation (DNAme) landscape is established early in development but remains highly dynamic within focal regions that overlap with gene regulatory elements. The significance of these dynamic changes, particularly in the central nervous system, remains unresolved. Here, we utilize a powerful human embryonic stem cell differentiation model for the generation of motor neurons (MNs) in combination with genetic mutations in the de novo DNAme machinery. We quantitatively dissect the role of DNAme in directing somatic cell fate with high-resolution genome-wide bisulfite-, bulk-, and single-cell-RNA sequencing. We find defects in neuralization and MN differentiation in DNMT3A knockouts (KO) that can be rescued by the targeting of DNAme to key developmental loci using catalytically inactive dCas9. We also find decreased dendritic arborization and altered electrophysiological properties in DNMT3A KO MNs. Our work provides a list of DNMT3A-regulated targets and a mechanistic link between de novo DNAme, cellular differentiation, and human MN function.